Electronic device with an update agent that employs preprocessing techniques for update

ABSTRACT

Methods of updating an electronic device having an update agent employing preprocessing techniques is disclosed. The methods described permit an electronic device having a non-volatile memory to update a plurality banks in an efficient manner, by preprocessing the original contents of the non-volatile memory. The preprocessing may comprise shifting one or more banks before performing an update, so as to create a moving, unoccupied bank or “bubble” into which the updated version of a bank may be stored. An embodiment of the present invention provides a reduction in the processing of the original memory contents, and extends the life of the non-volatile memory devices used.

RELATED APPLICATIONS

This application is a continuation application of U.S. patentapplication Ser. No. 10/635,991 entitled “Electronic Device With AnUpdate Agent That Employs Preprocessing Techniques For Update”, filedAug. 7, 2003, which makes reference to, claims priority to and claimsbenefit from U.S. Provisional Patent Application Ser. No. 60/461,248,entitled “Electronic Device With An Update Agent That EmploysPreprocessing Techniques For Update”, filed on Apr. 8, 2003. Thisapplication makes reference to U.S. Provisional Patent Application Ser.No. 60/405,253, entitled “Firmware Update Network And Process EmployingPreprocessing Techniques”, filed on Aug. 22, 2002, U.S. ProvisionalPatent Application Ser. No. 60/415,620, entitled “System For GeneratingEfficient And Compact Update Packages”, filed on Oct. 2, 2002, U.S.Provisional Patent Application Ser. No. 60/441,867, entitled “MobileHandset Update Package Generator That Employs Nodes Technique”, filed onJan. 22, 2003, and U.S. Provisional Patent Application Ser. No.60/447,977, entitled “Update Package Generator Employing PartialPredictive Mapping Techniques For Generating Update Packages For MobileHandsets”, filed on Feb. 18, 2003.

INCORPORATION BY REFERENCE

The complete subject matter of each of the above-referenced UnitedStates Patent Applications is hereby incorporated herein by reference,in its entirety. In addition, this application makes reference to U.S.Provisional Patent Application Ser. No. 60/249,606, entitled “System andMethod for Updating and Distributing Information”, filed Nov. 17, 2000,and International Patent Application Publication No. WO 02/41147 A1,entitled “System and Method for Updating and Distributing Information”,publication date May 23, 2002, the complete subject matter of which arehereby incorporated herein by reference, in their entirety.

FEDERALLY SPONSORED RESEARCH OR DEVELOPMENT

[Not Applicable]

MICROFICHE/COPYRIGHT REFERENCE

[Not Applicable]

BACKGROUND OF THE INVENTION

Electronic devices such as, for example, mobile phones and personaldigital assistants (PDA's) contain firmware and application softwarethat are provided by the manufacturers of the electronic devices, bytelecommunication carriers, or by third parties. These firmware andapplication software often contain software errors or “bugs”. Inaddition, software developers may add new features over the life of thesoftware. Therefore, new versions of the firmware and software areperiodically released to fix the bugs, to introduce new features, orboth.

The process of updating such a device is relatively complex, and thereare many potential sources of interruption of the update process. Theseinclude exhaustion of the battery operating the device, loss of thecommunication link used for the update, and interruption by outgoing orincoming calls. If the fitnware/software of a mobile handset is updatedand the mobile handset becomes inoperative, the user is likely to bedisappointed with the service that disseminated the associatedfirmware/software update. For these reasons, firmware/software updatesin mobile handsets need to be fault-tolerant. Unfortunately, thesedevices are constrained in many ways, and achieving fault-tolerantbehavior is not easy, requiring great care in the design and managementof related activities.

Further limitations and disadvantages of conventional and traditionalapproaches will become apparent to one of ordinary skill in the artthrough comparison of such systems with the present invention as setforth in the remainder of the present application with reference to thedrawings.

BRIEF SUMMARY OF THE INVENTION

Aspects of the present invention may be found in a method of updating anelectronic device from a first code version to a second code versionaccording to a bank order, the electronic device having a non-volatilememory comprising a reserved area and a plurality of banks containingthe first code version. Such a method may comprise moving the contentsof the last bank in the bank order to the reserved area of thenon-volatile memory. The method may also comprise shifting the contentsof each bank in the bank order to the next bank in the bank orderbeginning with the penultimate bank in the bank order, and proceeding indescending bank order until the contents of the first bank in the bankorder has been shifted to the second bank in the bank order. The methodmay comprise converting the contents of each bank in the bank order fromthe first code version to the second code version in a fault tolerantmanner beginning with the second bank in the bank order and proceedingin ascending bank order until the last bank in the bank order has beenconverted, each converted bank being stored in the previous bank in thebank order.

The method may further comprise transforming the contents of thereserved area from the first code version to the second code version ina fault tolerant manner, the second code version being stored in thebank that is last in the bank order. At least one of the moving and theshifting may be performed coincident with at least one preprocessingtechnique. The at least one preprocessing technique may use at least onepreprocessing instruction, and may comprise at least one of a bubblestechnique, a nodes technique, and a shift region technique. The updatingmay use only two writes to each non-volatile memory location beingupdated.

An embodiment of the present invention may also comprise receiving anupdate package comprising at least one of at least a preprocessinginstruction, an update instruction, and a bank order specification,where the receiving may use a public network and the receiving may use awireless network. At least one of the converting and the transformingmay use at least one update instruction, and at least one of the movingand shifting may use an offset of more than one bank.

Additional aspects of the present invention may be found in a method ofoperating an electronic device, the electronic device having anon-volatile memory comprising a reserved area and a plurality of bankscontaining a first code version. An embodiment of the present inventionmay comprise moving the contents of a designated bank to the reservedarea of the non-volatile memory, the designated bank thereby becoming anunoccupied bank. In addition, the embodiment may comprise shifting thecontents of each of the plurality of banks other than the designatedbank from an original bank to an unoccupied bank in a bank by bankfashion, each original bank thereby temporarily becoming an unoccupiedbank. An embodiment of the present invention may further compriseconverting the contents of each of the plurality of banks other than thedesignated bank from the first code version to a second code version ina fault tolerant manner beginning with the contents of the last bankshifted and proceeding in reverse order of the shifting. The second codeversion of each bank may be stored into the original bank from which thefirst code version of the bank was shifted. An embodiment in accordancewith the present invention may also comprise transforming the contentsof the reserved area of the non-volatile memory from the first codeversion to a second code version in a fault tolerant manner, the secondcode version being stored in the designated bank.

In an embodiment of the present invention, at least one of the moving,shifting, converting, and transforming may be performed according to aspecified bank order, and at least one of the moving and shifting maycomprise preprocessing the contents of at least one of the plurality ofbanks. The preprocessing may comprise at least one of rearranging thecontents of a bank, updating an address, updating a reference, andupdating a branch instruction, and at least one of the converting andtransforming may use at least one update instruction. The preprocessingmay use at least one of a bubbles technique, a nodes technique, and ashift regions technique, and may use at least one preprocessinginstruction.

An embodiment of the present invention may further comprise receiving anupdate package comprising at least one of a preprocessing instruction,an update instruction, and a bank order specification, where thereceiving may use a public network, and the receiving may use a wirelessnetwork.

Further aspects of the present invention may be found in a method ofupdating an electronic device having a non-volatile memory comprising atleast a first bank and a second bank, the at least a first bank and asecond bank containing a first code version. An embodiment in accordancewith the present invention may comprise moving the contents of thesecond bank to a reserve bank, transferring the contents of the firstbank to the second bank, and converting the contents of the second bankto an updated version of the first bank. The method may further comprisestoring the converted contents of the second bank into the first bank,transforming the contents of the reserve bank into an updated version ofthe second bank, and copying the transformed contents of the reservebank to the second bank.

At least one of the converting and the transforming may use at least oneupdate instruction, and at least one of the moving and the transferringmay comprise preprocessing the contents of at least one of the pluralityof banks. The preprocessing may comprise at least one of rearranging thecontents of a bank, updating an address, updating a reference, andupdating a branch instruction. The preprocessing may use at least one ofa bubbles technique, a nodes technique, and a shift regions technique,and may use at least one preprocessing instruction.

At least one of the moving, transferring, converting, storing,transforming, and copying may use a specified bank order. In addition,the method may comprise receiving an update package comprising at leastone of a preprocessing instruction, an update instruction, and a bankorder specification, where the receiving may use a public network, andthe receiving may use a wireless network.

Yet other aspects of the present invention may be observed in a methodof updating an electronic device from a first code version to a secondcode version, the electronic device having a non-volatile memorycomprising a plurality of banks containing the first code version, themethod comprising converting the first code version to the second codeversion in a fault tolerant manner, wherein the method requires only twowrites to each bank being updated.

These and other features and advantages of the present invention may beappreciated from a review of the following detailed description of thepresent invention, along with the accompanying figures in which likereference numerals refer to like parts throughout.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a block diagram of an exemplary update network for dispensingan update package to an electronic device, the electronic deviceemploying an update agent to update its operating system, applicationssoftware, and/or firmware, in accordance with the present invention.

FIG. 2 is a block diagram depicting the operation of an exemplary “firstbank bubble”-based preprocessing technique that may be employed by anupdate agent in an electronic device such as the electronic deviceillustrated in FIG. 1, in accordance with the present invention.

FIG. 3 is a block diagram depicting the operation of another exemplary“first bank bubble”-based preprocessing technique that may be employedby an update agent in an electronic device such as the electronic deviceillustrated in FIG. 1, in accordance with the present invention.

DETAILED DESCRIPTION OF THE INVENTION

Aspects of the present invention relate to the updating offirmware/software components in electronic devices such as mobilehandsets and personal digital assistants. More specifically, aspects ofthe present invention relate to a fault tolerant method of updatingmemory involving preprocessing the memory prior to performing an updatein order to reduce the amount of data copied, the time needed to performthe update, and to extend the life of the updated memory.

FIG. 1 is a block diagram of an exemplary update network 105 fordispensing an update package 123 to an electronic device 107, theelectronic device 107 employing an update agent 113 to update itsoperating system 119, applications software 121, and/or firmware 117, inaccordance with the present invention. The update package 123 isproduced by a generator 131 and processed by the update agent 113, toupdate the firmware and software of electronic device 107 in afault-tolerant mode employing bank-by-bank update techniques.

The network 105 comprises an electronic device 107, a device server 127,an update store 129, and a generator 131. The electronic device 107 iscommunicatively coupled to the device server 127, which iscommunicatively coupled to the update store 129. The communication linkbetween the electronic device 107 and the device server 127 may be, forexample, a wired network, a wireless network, a public network, anInternet-based network, and an intranet-based network, or anycombination of the above. The update store 129 has stored within it acollection of update packages produced by the generator 131. The updatepackages stored within update store 129 are communicated to deviceserver 127 for distribution to and processing by the electronic device107. In one embodiment of the present invention, the device server 127,the update store 129, and the generator 131 may be co-located on asingle computer or grouped in any combination on a networked cluster ofcomputers.

The electronic device 107 comprises a volatile random access memory(RAM) 125 and a non-volatile memory 109. The volatile memory 125 may beused for the execution of programs and for the temporary storage ofprogram variables. The non-volatile memory 109 is comprised of aplurality of banks or blocks and may be used for the storage ofprograms, update packages, and for other non-volatile storage. Thenon-volatile memory 109 comprises a loader 111, an update agent 113, apreprocessor 115, a firmware 117, an operating system (OS) 119, one ormore applications 121, and at least one update package 123. In aparticular embodiment of the present invention the preprocessor 115 mayalso be a part of the update agent 113.

In one embodiment of the present invention, the generator 131 mayprocess a first version and a second version of the firmware of theelectronic device 107 in order to produce a set of preprocessinginstructions, and difference information comprising a set of updateinstructions. The preprocessing instructions and the update instructionsmay be assembled into an update package. The update packages generatedby the generator 131 may be stored in the update store 129 forsubsequent retrieval by the electronic device 107, via the device server127. Once retrieved from the update store 129, an update package may beused by electronic device 107 to convert or transform portions of itsfirmware/software from the first version to the second version in abank-by-bank fashion.

The update agent 113 in an embodiment of the present invention mayemploy the preprocessor 115 as a part of the processing of the updatepackage 123. In such an embodiment, the preprocessor may shift selectedbanks of non-volatile memory 109 by a distance equal to, for example,the size of one or more banks, according to a bank order. In thisdiscussion, the terms “bank” or “block” may be used to represent aportion of non-volatile memory 109. The shifting of selected banks ofthe non-volatile memory 109 allows an embodiment of the presentinvention to eliminate the need to “back up” the bank being updatedduring a subsequent fault tolerant update process. An example faulttolerant update process is described in U.S. Provisional PatentApplication Ser. No. 60/434,712, entitled “Mobile Handset With A FaultTolerant Update Agent”, filed Dec. 18, 2002, the complete subject matterof which is hereby incorporate by reference herein, in its entirety.

For example, prior to performing a fault tolerant update, thepreprocessor 115 may move the firmware 117 and/or software 119, 121portions of the non-volatile memory 109 by the size of at least onebank, initially creating an unoccupied first bank or “first bankbubble”. This may be done as a part of other preprocessing operationssuch as, for example, a “bubbles” preprocessing technique, a “nodes”preprocessing technique, or a “shift regions” preprocessing technique,and may be performed according to a bank order specification containedwithin an update package. An example of a suitable “bubbles”preprocessing technique may be found in U.S. Provisional PatentApplication Ser. No. 60/405,253, entitled “Firmware Update Network AndProcess Employing Preprocessing Techniques”, filed on Aug. 22, 2002. Anexample of another “bubbles”-type preprocessing technique may be foundin U.S. Provisional Patent Application Ser. No. 60/415,620, entitled“System For Generating Efficient And Compact Update Packages”, filed onOct. 2, 2002. An example of a “nodes” preprocessing technique may befound in U.S. Provisional Patent Application Ser. No. 60/441,867,entitled “Mobile Handset Update Package Generator That Employs NodesTechnique”, filed on Jan. 22, 2003. Finally, a suitable “shift regions”preprocessing technique is described in U.S. Provisional PatentApplication Ser. No. 60/447,977, entitled “Update Package GeneratorEmploying Partial Predictive Mapping Techniques For Generating UpdatePackages For Mobile Handsets”, filed on Feb. 18, 2003. The completesubject matter of each of the United States patent applications listedabove is hereby incorporated herein, in its entirety. The unoccupiedbank or “bubble” may then be used by the update agent 113 as a movingbubble or destination bank into which the updated firmware/softwarebanks are written, after each of them have been updated in the RAM 125.An embodiment of the present invention may combine the shifting of a setof banks of firmware with other preprocessing activities such as, forexample, the updating of addresses, references, link instructions, etc.that may be performed during the preprocessing methods of the abovereferences. The “first bank bubble” technique described herein may beused whether or not other preprocessing techniques are employed.

FIG. 2 is a block diagram depicting the operation of an exemplarypreprocessing technique that may be employed by an update agent in anelectronic device such as the electronic device 107 illustrated in FIG.1, in accordance with the present invention. The illustration of FIG. 2shows a non-volatile memory 209 having banks 1 to N, prior to theapplication of the “first bank bubble” preprocessing technique, and anon-volatile memory 211 having banks 1 to N and bubble 213 correspondingto the non-volatile memory 209, following the application of the “firstbank bubble” preprocessing technique. In the exemplary embodimentillustrated in FIG. 2, a bank order specification is not used. Apreprocessor such as the preprocessor 115 of FIG. 1 may shift selectedbanks of the firmware contained in non-volatile memory 209 by the sizeof one or more banks. This shift of the contents of the non-volatilememory 209 creates an empty bank or “bubble”, illustrated in FIG. 2 asbubble 213 in the non-volatile memory 211. The shifting of the banks ofnon-volatile memory 209 may be performed by an update agent, such as theupdate agent 113 of FIG. 1, as a part of performing other preprocessingoperations described above. The illustration of FIG. 2 shows a situationwhere all N banks of the non-volatile memory 209 are modified in asequential fashion beginning with bank 1. An embodiment of the presentinvention may also be applied to updates of memory, such as non-volatilememory 209, where not all banks within the memory are being updated, andwhere the order of the bank update is not a sequential order.

As described above, an explicit bank order specification may not beincluded in the update package. In such an embodiment, the update agentmay first move one or more banks of non-volatile memory 209 in asequential fashion, as shown in FIG. 2. The movement of these banks maybe combined with other preprocessing operations and may begin by movingthe contents of bank N to a designated or reserved area of non-volatilememory 209. Bank N-1 may then be moved to bank N, bank N-2 moved to bankN-1, and so on until bank 1 is moved to bank 2. In this manner, anempty/unoccupied bank or “bubble” is created at bank 1.

Following the shifting of the banks to be updated, the update agent maybegin updating the non-volatile memory starting with bank 1. The updateagent may copy the contents of bank 2 to a designated “working bank” involatile memory, such as the RAM 125 of FIG. 1. The update agent maythen use update instructions for bank 1 that are contained in the updatepackage to update the contents of the working bank. Upon updating theworking bank, the update agent may store the contents of the workingbank into the currently unoccupied bank 1. The update agent may use acyclic redundancy check (CRC), MD5 checksum, or other calculated valueto verify the success of the update. The update agent may then updatethe now unoccupied bank 2, using the original contents of bank 2 thatwas stored in bank 3, and continue in like manner until bank N-1 isupdated. Finally, bank N may be updated using the original bank Ncontents that was stored in the designated reserved or backup location.In this manner, an embodiment of the present invention may combine theshifting of a set of banks of firmware with other preprocessingactivities as described above, reducing the number of writes to eachupdated memory location from four writes per updated memory location totwo writes per updated memory location, while also providing completefault tolerance. This minimizes the number of writes to non-volatilememory, reducing the time needed to update the memory, and extending thelife of the non-volatile memory devices that are typically used in suchapplications.

FIG. 3 is a block diagram depicting the operation of another exemplary“first bank bubble”-based preprocessing technique that may be employedby an update agent in an electronic device such as the electronic device107 illustrated in FIG. 1, in accordance with the present invention. Theillustration of FIG. 3 shows a first, original arrangement of anon-volatile memory 309, and a second, preprocessed arrangement of thenon-volatile memory 311. In the example illustrated in FIG. 3, theupdate package received by the electronic device 107 of FIG. 1 includesa bank order specification (a.k.a., “bank order”). The bank order may bedefined by a generator such as generator 131 of FIG. 1 at the time theupdate package is created. The use of a bank order specification in theupdate process may permit a generator, such as the generator 131 of FIG.1, to produce a more compact and efficient update package. Apreprocessor, such as the preprocessor 115 of FIG. 1, may use the bankorder contained in an update package to move one or more banks of anon-volatile memory such as non-volatile memory 309 prior to performingthe update of the affected banks. In an embodiment of the presentinvention, a preprocessor such as the preprocessor 115 of FIG. 1 mayalso be contained within an update agent, such as the update agent 113of FIG. 1. As described above, the shifting operations used by anembodiment of the present invention may be in addition to and combinedwith other operations indicated in the update package.

Using the bank order specification, the preprocessor may first move thecontents of the last bank in the bank order to a designated reserved orbackup bank in the arrangement of non-volatile memory 311. Thepreprocessor may then move the bank in position N-1 in the bank order tothe location of the bank in position N in the bank order, then move thebank in position N-2 in the bank order to the location of the bank inposition N-1 in the bank order, and so on. This sequence of movescontinues until the bank that is first in the bank order is moved to thememory location of the bank that is second in the bank order. In thismanner, an empty or unoccupied bank or “bubble” is created thatcorresponds to the first bank in the bank order.

For example, let us assume that a bank order specification is containedin the update package to be used in updating the non-volatile memory 309of FIG. 3. Let us further assume that the bank order specification is asshown in FIG. 3, (2, N-1, 3, 1, N), indicating that the banks ofnon-volatile memory 309 are to be updated in the order bank 2, bank N-1,bank 3, bank 1, and bank N. In an embodiment of the present invention, apreprocessor, such as the preprocessor 115 of FIG. 1, may use the bankorder specification to move the affected banks of non-volatile memory309 in the reverse of the bank order specification. As shown in thearrangement of non-volatile memory 311 of FIG. 3, the last bank in thebank order specification, bank N of the arrangement of non-volatilememory 309, is moved to a reserved or “backup” bank in the preprocessedarrangement of the non-volatile memory 311. Then, the next-to-last bankin the bank order specification, bank 1 of the arrangement ofnon-volatile memory 309, is moved to the vacant bank created when bank Nwas moved to the backup bank in the arrangement of non-volatile memory311. Next bank 3 in the arrangement of non-volatile memory 309 is movedto the vacant bank created when bank 1 was move to bank N of thearrangement of nonvolatile memory 311. This sequence of bank-to-bankmoves continues until the first bank in the bank order specification, inthis case bank 2, is moved to reside in the original location of thesecond bank in the bank order, in this case bank N-1. The result is avacant/unoccupied bank or “bubble” 313 at the original location of thefirst bank in the bank order, bank 2.

Following the shifting of the banks to be updated, an update agent, suchas the update agent 113 of FIG. 1, updates the preprocessed non-volatilememory 311 starting with the first bank in the bank order. The updateagent may first copy the contents of the second bank in the bank order,bank N-1, that contains the contents of the first bank in the bankorder, bank 2, to a designated “working bank” in volatile memory, suchas the RAM 125 of FIG. 1. The update agent 113 may then use the updateinstructions contained in the update package that apply to the firstbank in the bank order, in this case bank 2, to update the contents ofthe working bank. In one embodiment, the update may be performed byconverting or transforming the contents of the working bank using updateinstructions contained in an update package. Upon updating the workingbank, the update agent may copy the contents of the working bank intothe first (currently unoccupied) bank in the bank order, bank 2. Theupdate agent may calculate a cyclic redundancy check (CRC), MD5checksum, or other value to verify the success of each of the steps ofthe update. The update agent may then update the now unoccupied secondbank in the bank order in the same manner, using the original contentsof the second bank that is stored in the third bank in the bank order.The update continues in like manner until the next-to-last bank in thebank order is updated. Finally, the last bank in the bank order isupdated, in this example bank N, using the original bank N contentsstored in the designated reserved or backup location. In this manner, anembodiment of the present invention reduces the amount of copying of thecontents of the memory being updated, reducing the time needed to updatethe memory, and extending the life of the memory devices that aretypically used in such applications.

As discussed above, the preprocessing activities defined by thegenerator 131 of FIG. 1 and described in the update package received bythe electronic device 107 of FIG. 1 may be combined with the shiftingoperations described above with respect to FIGS. 2 and 3. In the processdescribed above, banks of a non-volatile memory 309 are moved bypreprocessing activities to create an empty or unoccupied bank, shown asbubble 313 in the arrangement of non-volatile memory 311. In thediscussion above and the associated illustrations of FIGS. 2 and 3, thisshifting creates an unoccupied bank or “bubble” equal to the size of onebank. In another embodiment, however, the shifting of firmware/softwarecode using other bubble sizes, such as the size of multiple banks, isalso possible.

Aspects of the present invention provide a network having a plurality ofelectronic devices and that employs a generator to produce updatepackages for the electronic devices. A corresponding update agent in theelectronic devices uses the update packages to update its firmwareand/or software. The generator specifies preprocessing steps thatincorporate shifting of firmware and/or software code by one or morememory banks so as to create a “first bank bubble” in the non-volatilememory of the electronic device during a preprocessing activity. Apreprocessor or update agent in the electronic device subsequentlyemploys the “first bank bubble” as a moving bubble or vacant bank toconduct an efficient and fault tolerant update.

While the present invention has been described with reference to certainembodiments, it will be understood by those skilled in the art thatvarious changes may be made and equivalents may be substituted withoutdeparting from the scope of the present invention. In addition, manymodifications may be made to adapt a particular situation or material tothe teachings of the present invention without departing from its scope.Therefore, it is intended that the present invention not be limited tothe particular embodiment disclosed, but that the present invention willinclude all embodiments falling within the scope of the appended claims.

1. A computer-readable storage, having stored thereon a computer programhaving a plurality of code sections for updating an electronic devicehaving a non-volatile memory comprising a reserved area and a pluralityof banks containing a first code version from the first code version toa second code version according to a bank order having a penultimatebank, the code sections executable by a processor for causing theprocessor to perform the operations comprising: moving the contents ofthe last bank in the bank order to the reserved area of the non-volatilememory; shifting the contents of each bank in the bank order to the nextbank in the bank order beginning with the penultimate bank in the bankorder, and proceeding in descending bank order until the contents of thefirst bank in the bank order has been shifted to the second bank in thebank order; converting the contents of each bank in the bank order fromthe first code version to the second code version in a fault tolerantmanner beginning with the second bank in the bank order and proceedingin ascending bank order until the last bank in the bank order has beenconverted, each converted bank being stored in the previous bank in thebank order; and transforming the contents of the reserved area from thefirst code version to the second code version in a fault tolerantmanner, the second code version being stored in the bank that is last inthe bank order.
 2. The computer-readable storage of claim 1 wherein atleast one of the moving and the shifting is performed coincident with atleast one preprocessing technique.
 3. The computer-readable storage ofclaim 2 wherein the at least one preprocessing technique comprises atleast one of a bubbles technique, a nodes technique, and a shift regiontechnique.
 4. The computer-readable storage of claim 1 wherein theupdating uses only two writes to each non-volatile memory location beingupdated.
 5. The computer-readable storage of claim 1 wherein the codesections are executable by the processor to cause the processor toperform the operations comprising: receiving an update packagecomprising at least one of at least a preprocessing instruction, anupdate instruction, and a bank order specification.
 6. Thecomputer-readable storage of claim 5 wherein the receiving uses awireless network.
 7. The computer-readable storage of claim 1 wherein atleast one of the moving and shifting uses an offset of more than onebank.
 8. The computer-readable storage of claim 1 wherein the electronicdevice comprises a mobile handset.
 9. One or more circuits for use in anelectronic device, the one or more circuits comprising: a non-volatilememory comprising a reserved area and a plurality of banks containing afirst code version; and at least one processor communicatively coupledto the non-volatile memory, the at least one processor operating to, atleast: move the contents of a designated bank to the reserved area ofthe non-volatile memory, the designated bank thereby becoming anunoccupied bank; shift the contents of each of the plurality of banksother than the designated bank from an original bank to an unoccupiedbank in a bank by bank fashion, each original bank thereby temporarilybecoming an unoccupied bank; convert the contents of each of theplurality of banks other than the designated bank from the first codeversion to a second code version in a fault tolerant manner beginningwith the contents of the last bank shifted and proceeding in reverseorder of the shifting, the second code version of each bank being storedinto the original bank from which the first code version of the bank wasshifted; and transform the contents of the reserved area of thenon-volatile memory from the first code version to a second code versionin a fault tolerant manner, the second code version being stored in thedesignated bank.
 10. The one or more circuits of claim 9 wherein atleast one of the moving, shifting, converting, and transforming isperformed according to a specified bank order.
 11. The one or morecircuits of claim 9 wherein at least one of the moving and shiftingfurther comprises preprocessing the contents of at least one of theplurality of banks.
 12. The one or more circuits of claim 11 wherein thepreprocessing comprises at least one of rearranging the contents of abank, updating an address, updating a reference, and updating a branchinstruction.
 13. The one or more circuits of claim 11 wherein thepreprocessing uses at least one of a bubbles technique, a nodestechnique, and a shift regions technique.
 14. The one or more circuitsof claim 9 further comprising: receiving an update package comprising atleast one of a preprocessing instruction, an update instruction, and abank order specification.
 15. The one or more circuits of claim 14wherein the receiving uses a public network.
 16. The one or morecircuits of claim 14 wherein the receiving uses a wireless network. 17.The one or more circuits of claim 9 wherein the updating of banks isperformed according to a specified bank order.
 18. The one or morecircuits of claim 9 wherein the electronic device comprises a mobilehandset.